JP2013143701A - Optical system, optical line device, and optical network device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cut back power consumption by lowering a transmission rate when a PON system has trouble.SOLUTION: An optical line device has transmission rate information indicating a minimum speed of a signal transmitted and received between the optical line device and an optical network device, so that when abnormality information indicating that the optical line device or the optical network device is not normally supplied with power is received, the optical line device determines on the basis of the transmission rate information a first downlink clock rate at which a downlink signal is transmitted to the optical network device and a first uplink clock rate at which an uplink signal is received from the optical network device, and then determines first timing with which a downlink clock rate in the optical line device needed for transmitting a downlink signal to the optical network device is changed to the first downlink clock rate and second timing with which an uplink clock rate in the optical line device needed for receiving an uplink signal from the optical network device is changed to the first uplink clock rate.

Description

  The present invention relates to an optical system, and more particularly to an optical system having a power saving function.

  In order to meet these demands while increasing the speed and bandwidth of communication networks, optical networks have been introduced. In the optical network, one station side optical transmission line termination device (hereinafter referred to as OLT) and one in-home optical transmission line termination device (hereinafter referred to as ONU) are connected via an optical fiber. Network that communicates point-to-point.

  In addition, in a passive optical network (hereinafter referred to as PON), one OLT communicates with a plurality of ONUs and a star type point-to-multipoint via an optical fiber and an optical splitter that branches the optical fiber. Network.

  As typical PON standards, EPON (Ethernet (registered trademark, hereafter the same) PON) standardized in IEEE 802.3, ITU-T G. There is GPON (Gigabit Capable PON) standardized in 984. The upstream frame transmitted from the ONU toward the OLT and the downstream frame transmitted from the OLT toward the ONU are multiplexed by wavelength division multiplexing (hereinafter referred to as WDM) in the PON.

  The OLT transmits the same data to all ONUs connected by the OLT and the optical fiber by transmitting the downstream frame. When receiving the downlink frame, the ONU refers to the destination information included in the preamble part of the downlink frame, and discards the frames other than the downlink frame addressed to itself. Furthermore, the ONU transfers only the data included in the downlink frame addressed to itself to the user side.

  On the other hand, the ONU multiplexes uplink frames using time division multiplexing (hereinafter referred to as TDM) that outputs data at a time specified by transfer permission from the OLT. Then, the multiplexed upstream frame is transmitted to the OLT.

  Also, PON is a system that transmits and receives low-speed signals such as a communication speed of 64 kbit / sec, BPON (Broadband PON) that transmits and receives fixed-length ATM cells at a maximum of approximately 600 Mbit / sec, and maximum variable-length packets of Ethernet Introduction of EPON that transmits and receives at about 1 Gbit / second or GPON that transmits and receives a signal of about 2.4 Gbit / second is underway. Furthermore, in the future, it is required to realize a high-speed PON capable of transmitting and receiving signals of 10 Gbit / second to 40 Gbit / second.

  As the communication speed of the PON increases, the power consumption of the relay device on the transmission path is also increasing. Many ONUs are installed on the network because they are installed at the subscriber's home. On the other hand, the ONU requires a shorter time for using a usable bandwidth than the OLT and the upper switch group. Therefore, the ONU is often left unattended when it is not communicating.

  In order to cope with such a state, when a TE (Terminal Equipment: hereinafter referred to as TE) is not connected to the ONU via a LAN cable, by setting the function block inside the ONU to the low power consumption mode, A method for reducing power consumption in an ONU is disclosed (for example, see Patent Document 1).

  In addition, a method is disclosed in which an ONU is set in a sleep state by issuing a sleep request from the ONU to the OLT and performing a procedure in which the OLT issues a permission (see, for example, Patent Document 2).

JP 2008-113193 A JP 2009-260970 A

  When a power failure or power saving is required due to a wide-area disaster or a failure in the power supply function, power supply for operating the optical access transmission facility is insufficient, and the operation of the facility cannot be maintained. Then, there arises a situation where a truly indispensable minimum communication function cannot be provided.

  A communication network is a lifeline that supports a smooth civil life. Even if it is unavoidable that some of the functions deteriorate due to the abnormalities described above, it is necessary to effectively use limited power to meet urgent communication requirements. Is very important. In particular, the ratio of power consumed by the optical access equipment in the entire communication network is large, and it is significant to operate the optical access equipment with minimum power consumption.

  On the other hand, as described above, the power consumption of the relay device on the transmission path is increasing while the high-speed and large-capacity communication is progressing, so in order to provide a minimum communication function in the event of an abnormality such as a power failure, It is necessary to reduce the power consumption by reducing the transmission speed.

  However, the conventional PON system is designed to operate at a fixed clock frequency designed in advance, and the reduction of the transmission speed (or transmission clock speed) according to the power supply status is described in the above-mentioned patent document. 1 and Patent Document 2 are not described. Also, when switching the transmission rate, it is necessary to avoid a situation where a user signal is lost and time is required for retransmission.

  In view of these problems, the present invention provides a specific means for mounting a PON system that reduces power consumption by reducing the transmission speed even in the event of a failure in which power is not supplied, and provides a minimum communication function. The purpose is to provide. It is another object of the present invention to provide a PON system that can reduce missing user signals even when the transmission rate is switched.

  According to a representative aspect of the present invention, an optical system comprising an optical line device for transmitting a signal and an optical network device for receiving a signal from the optical line device, wherein the optical line device is the optical line. Acquire transmission rate information indicating a minimum speed of a signal transmitted and received between a device and the optical network device, and abnormal information indicating that power is not normally supplied to the optical line device or the optical network device. A power monitoring unit, and when the abnormality information is acquired by the power monitoring unit, based on the transmission rate information, a first downlink clock rate for the optical line device to transmit a downlink signal to the optical network device; The first speed control unit for determining a first upstream clock speed for receiving the upstream signal from the optical network device, and the abnormality information is received by the power monitoring unit. If obtained, a first timing for changing a downlink clock rate in the optical line device for transmitting a downlink signal to the optical network device to the first downlink clock rate, and an uplink signal from the optical network device A bandwidth control unit for determining a second timing for changing an upstream clock rate in the optical line device for receiving the first upstream clock rate to the first upstream clock rate.

  According to an embodiment of the present invention, a minimum communication function can be provided when power supply is reduced.

1 is a block diagram showing a network including a PON system according to a first embodiment of the present invention. It is a block diagram which shows the process part with which OLT of the 1st Embodiment of this invention is equipped. It is a block diagram which shows the process part with which ONU of the 1st Embodiment of this invention is equipped. It is a flowchart which shows the process which synchronizes the transmission clock speed by OLT of the 1st Embodiment of this invention. It is explanatory drawing which shows the transmission rate management table of the 1st Embodiment of this invention. It is explanatory drawing which shows the time stamp management table of the 1st Embodiment of this invention. It is explanatory drawing which shows the format of the clock change notification of the 1st Embodiment of this invention. It is a flowchart which shows the process which synchronizes the transmission clock rate by ONU of the 1st Embodiment of this invention. It is a sequence diagram which shows the synchronous process of the transmission clock speed of the 1st Embodiment of this invention. It is a flowchart which shows the process which synchronizes the transmission clock speed by OLT of the 2nd Embodiment of this invention. It is explanatory drawing which shows the time stamp management table of the 2nd Embodiment of this invention. It is a flowchart which shows the process which synchronizes the transmission clock rate by ONU of the 2nd Embodiment of this invention. It is a sequence diagram which shows the process which changes the transmission clock speed of the 2nd Embodiment of this invention. It is a flowchart which shows the process which synchronizes the transmission clock speed by OLT of the 3rd Embodiment of this invention. It is explanatory drawing which shows the time stamp management table of the 3rd Embodiment of this invention. It is a flowchart which shows the process which synchronizes the transmission clock rate by ONU of the 3rd Embodiment of this invention. It is a sequence diagram which shows the synchronous process of the transmission clock speed of the 3rd Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail.

(First embodiment)
FIG. 1 is a block diagram illustrating a network including a PON system according to a first embodiment of this invention.

  The PON system of the present embodiment includes an upper network 1, an OLT 2, an optical splitter 3, a plurality of ONUs, and a plurality of terminal devices.

  Although only two ONUs 4 and 5 are shown in FIG. 1, a plurality of ONUs may be connected to the OLT 2 via the optical splitter 3. Moreover, although the terminal device shown in FIG. 1 is only two, the terminal device 6 and the terminal device 7, a some terminal device may be connected to each ONU.

  The OLT 2 is connected to the power transmission network management system 11 via an EMS (Element Management System) 8. The OLT 2 is connected to the battery 12, the ONU 4 is connected to the battery 13, and the ONU 5 is connected to the battery 14. The power transmission network management system 11, the battery 12, the battery 13, and the battery 14 are connected to the power transmission network 10.

  When the OLT 2 receives a signal for requesting data stored in the upper network 1 from the terminal device 6 via the ONU 4 and the optical splitter 3, the OLT 2 receives the requested data from the upper network 1, and receives the optical splitter 3 and the ONU 4 Is transmitted to the terminal device 6 via. When the OLT 2 receives a signal requesting data stored in the upper network 1 from the terminal device 7 via the ONU 5 and the optical splitter 3, the OLT 2 receives the requested data from the upper network 1 and receives the optical splitter 3. And transmitted to the terminal device 7 via the ONU 5.

  The OLT 2 communicates with the ONU 4 and the ONU 5 using optical signals multiplexed by WDM. Therefore, the upstream communication and the downstream communication between the OLT 2 and the ONU 4 and the ONU 5 do not collide.

  On the other hand, a plurality of ONUs transmit signals to the OLT 2 using the same wavelength. For this reason, the OLT 2 controls the transmission time of the optical signal of each ONU so that the transmission of the optical signal by TDM does not overlap the same time.

  The power transmission network 10 supplies power to the OLT 2, the ONU 4, and the ONU 5 through the battery 12, the battery 13, and the battery 14. The power transmission network management system 11 is a system that stops power supply from the power transmission network 10 to each battery or reduces the amount of power supply in accordance with a user instruction.

  The battery 12, the battery 13, and the battery 14 are backup power supply devices that supply power to the OLT 2, ONU 4, and ONU 5 when the power supplied from the power transmission network 10 to the OLT 2, ONU 4, and ONU 5 decreases or stops. In addition, the battery 12, the battery 13, and the battery 14 monitor the status of power supplied from the power transmission network 10 and the capacity of each battery, and notify the OLT 2, ONU 4, or ONU 5 of a power-off notification.

  When the power supplied to the OLT 2, ONU 4, or ONU 5 to which the battery 12, the battery 13, and the battery 14 are connected decreases or stops, a power-off notification is sent to the OLT 2, ONU 4, or ONU 5 to which the battery 12, the battery 13, and the battery 14 are connected. Send. The ONU 4 and the ONU 5 transfer the power-off notification to the OLT 2 when receiving the power-off notification.

  The EMS 8 is a system for remotely managing the OLT 2, the ONU 4 and the ONU 5, and acquires information on the power supply indicating the presence / absence of a power outage request or power saving request, the scheduled time of the planned power outage, and the like. And when the information regarding the acquired power supply shows the reduction | decrease or stop of the electric power to supply, a power-off notification is transmitted to OLT2.

  FIG. 2 is a block diagram illustrating a processing unit included in the OLT 2 according to the first embodiment of this invention.

  The OLT 2 includes a signal transmission / reception unit 201, an electro-optical conversion unit 202, a medium access control unit 203, a control unit 204, and a power supply circuit 211. The OLT 2 includes a time counting circuit (not shown).

  The signal transmission / reception unit 201 is a processing unit for acquiring data from the higher level network 1 by communicating with a relay device provided in the higher level network 1. The electro-optical conversion unit 202 is a processing unit for converting an electric signal into an optical signal in order to communicate with the ONU 4 and the ONU 5 using an optical signal.

  The medium access control unit 203 is a processing unit for controlling data transmitted from the OLT 2 to the ONU 4 and the ONU 5 according to whether the ONU 4 and the ONU 5 are in operation or in the sleep period. Further, the medium access control unit 203 of the present embodiment measures the round trip delay time of the signal between the OLT 2 and the ONU 4 and the round trip delay time of the signal between the OLT 2 and the ONU 5 by referring to the time counting circuit provided in the OLT 2. To do.

  The power supply circuit 211 is a circuit that supplies power to each processing unit of the OLT 2. The power supply circuit 211 is connected to the battery 12.

  The control unit 204 is a processing unit for performing processing for changing a transmission clock speed, which will be described later, of the OLT 2. The control unit 204 includes a transmission rate notification unit 205, a transmission rate control unit 206, a transmission rate management table 207, a bandwidth control unit 208, a time stamp management table 210, and a power monitoring unit 209.

  In addition, the control unit 204 transmits the output from each processing unit included in the control unit 204 to the medium access control unit 203, the signal transmission / reception unit 201, the power supply circuit 211, and the EMS 8, or the medium access control unit 203, the signal The data transmitted from the transmission / reception unit 201, the power supply circuit 211, and the EMS 8 is input to each processing unit included in the control unit 204. Furthermore, the control unit 204 inputs the output of each processing unit included in the control unit 204 to another processing unit that performs the next process, or inputs information about each table included in the control unit 204 to each processing unit. To do.

  The transmission rate notification unit 205 is a processing unit that generates a message to be transmitted to the ONU 4 or the ONU 5 in order to synchronize the transmission clock rate between the OLT 2 and the ONU 4 or the ONU 5. Further, it is a processing unit for receiving a message transmitted from the ONU 4 or the ONU 5.

  The transmission rate control unit 206 is a processing unit that determines a transmission clock rate between the OLT 2 and the ONU 4 or the ONU 5 based on the transmission rate management table 207.

  The transmission rate management table 207 indicates the transmission rate when the OLT 2 and the ONU are normally supplied with power from the transmission network 10 and the transmission rate when the power supplied from the transmission network 10 to the OLT 2 and the ONU is reduced or stopped. It is a table that contains. In the following, the case where the OLT 2 and the ONU are normally supplied with power from the power transmission network 10 is described as normal time, and the case where the power supplied from the power transmission network 10 to the OLT 2 and ONU is reduced or stopped is described as abnormal time. To do.

  The bandwidth control unit 208 is a processing unit that determines the timing for changing the transmission clock speed between the OLT 2 and the ONU 4 or the ONU 5 based on the time stamp management table 210.

  The time stamp management table 210 is a table that indicates the band at which the ONU 4 and the ONU 5 transmit the upstream frame, and the timing at which the ONU 4 and the ONU 5 change the transmission clock speed. Note that the time stamp management table 210 according to the present embodiment indicates a band in which the ONU 4 and the ONU 5 transmit an upstream frame by a time band from the start time to the end time.

  The power monitoring unit 209 receives a power-off notification from the battery 12 via the power circuit 211. In addition, the power monitoring unit 209 receives a power-off notification from the EMS 8. Further, the power monitoring unit 209 receives the power-off notification transmitted from the ONU 4 or the ONU 5 via the medium access control unit 203.

  When the power monitoring unit 209 receives a power-off notification from the battery 12, the EMS 8, the ONU 4, or the ONU 5, the power monitoring unit 209 determines to start the process of changing the transmission clock speed.

  When the electro-optic conversion unit 202 receives the upstream frame transmitted from the ONU 4 or the ONU 5, the medium access control unit 203 transmits the MAC address included in the upstream frame and the transmission source assigned to the upstream frame preamplifier unit. Information indicating the ONU is stored in association with the route information.

  Then, the medium access control unit 203 transmits the uplink frame received by the electro-optical conversion unit 202 to the signal transmission / reception unit 201. The signal transmission / reception unit 201 transmits the upstream frame received from the medium access control unit 203 to the upper network 1.

  When the signal transmission / reception unit 201 receives a downstream frame transmitted from the upper network 1, the medium access control unit 203 refers to the MAC address of the downstream frame and uses the accumulated path information to indicate information indicating the destination ONU. To the preamble part of the downstream frame.

  Then, the medium access control unit 203 transmits the downlink frame to which the information indicating the destination is given to the electro-optical conversion unit 202. The electro-optical conversion unit 202 transmits the downstream frame received from the medium access control unit 203 to the ONU 4 and the ONU 5 via the optical splitter 3.

  As described above, the medium access control unit 203 has a switching function of holding information indicating the ONU 4 and the ONU 5 and adding information to the downstream frame so that the destination ONU can receive the downstream frame.

  Each processing unit of the OLT 2 illustrated in FIG. 2 may be implemented by a plurality of integrated circuits including at least one processor and at least one memory. Further, the function of each processing unit illustrated in FIG. 2 may be implemented by a processor included in the OLT 2 executing a program corresponding to the function of each processing unit.

  For example, the OLT 2 may execute a transmission rate notification program by a processor included in the OLT 2 in order to implement the function of the transmission rate notification unit 205.

  Further, each processing unit of the OLT 2 illustrated in FIG. 2 may be integrated into one processing unit, or may be divided into a plurality of processing units according to the processing of each processing unit.

  FIG. 3 is a block diagram illustrating a processing unit included in the ONU 4 according to the first embodiment of this invention.

  FIG. 3 shows a processing unit of the ONU 4, but an ONU other than the ONU 4 (including the ONU 5) also includes the same processing unit as each processing unit of the ONU 4 shown in FIG.

  The ONU 4 includes an electrical transmission / reception unit 301, an electro-optical conversion unit 302, a medium access control unit 303, a control unit 304, and a power supply circuit 310. The ONU 4 includes a time coefficient circuit (not shown).

  The electric side transmitting / receiving unit 301 is a processing unit for the ONU 4 to communicate with the terminal device 6 by an electric signal. The electro-optical conversion unit 302 is a processing unit for the ONU 4 to communicate with the OLT 2 using an optical signal.

  The medium access control unit 303 is a processing unit for controlling data communication according to whether the ONU 4 is in operation or in the sleep period. In addition, the medium access control unit 303 according to the present embodiment synchronizes the time counting circuit included in the ONU 4 with the time counting circuit included in the OLT 2.

  The power supply circuit 310 is a circuit that supplies power to each processing unit of the ONU 4. The power supply circuit 311 is connected to the battery 13.

  The control unit 304 is a processing unit that performs processing for changing a transmission clock speed, which will be described later, in the ONU 4. The control unit 304 includes a transmission rate notification receiving unit 306, a transmission rate control unit 307, a time stamp management table 308, and a power monitoring unit 309.

  In addition, the control unit 304 transmits the output from each processing unit included in the control unit 304 to the medium access control unit 303, the electric side transmission / reception unit 301, and the power supply circuit 310, and the medium access control unit 303, electric side Data transmitted from the transmission / reception unit 301 and the power supply circuit 310 is input to each processing unit included in the control unit 304. Furthermore, the control unit 304 inputs the output of each processing unit included in the control unit 304 to another processing unit that performs the next process, or inputs information about each table included in the control unit 304 to each processing unit. To do.

  The transmission rate notification receiving unit 306 is a processing unit that receives a message transmitted from the OLT 2 in order to synchronize the transmission clock rates of the OLT 2 and the ONU 4, and a processing unit that generates a message to be transmitted to the OLT 2.

  The transmission rate control unit 307 is a processing unit that changes the transmission clock rate at which the medium access control unit 303 transmits the upstream frame based on the time stamp management table 308 according to the timing instructed by the OLT 2. Further, the processing unit changes the transmission clock rate at which the medium access control unit 303 receives a downstream frame based on the time stamp management table 308 according to the timing instructed by the OLT 2.

  The time stamp management table 308 is a table that holds the timing instructed from the OLT 2.

  The power monitoring unit 309 receives a power-off notification from the battery 13 via the power circuit 310. Then, the received power-off notification is transmitted to the OLT 2 via the medium access control unit 303.

  Each processing unit of the ONU 4 illustrated in FIG. 3 may be implemented by a plurality of integrated circuits including at least one processor and at least one memory. Further, the processor of the ONU 4 may implement the function of each processing unit shown in FIG. 3 by executing a program corresponding to the function of each processing unit.

  For example, the ONU 4 may execute the transmission rate notification reception program by a processor included in the ONU 4 in order to implement the function of the transmission rate notification reception unit 306.

  Further, each processing unit of the ONU 4 illustrated in FIG. 3 may be integrated into one processing unit, or may be divided into a plurality of processing units according to the processing of each processing unit.

  FIG. 4 is a flowchart illustrating a process of synchronizing the transmission clock speed by the OLT 2 according to the first embodiment of this invention.

  FIG. 4 shows a process in which the OLT 2 synchronizes the transmission clock speed with the ONU 4 connected to the OLT 2. However, the process shown in FIG. 4 may be performed by the OLT 2 and all ONUs.

  Steps 402 to 405 shown in FIG. 4 are executed periodically or at a timing designated by the user or the like when the OLT 2 and the ONU 4 are supplied with normal power.

  The medium access control unit 203 of the OLT 2 transmits a discovery instruction to the ONU 4 as defined in Chapter 64 of the IEEE 802.3 standard (402). When the medium access control unit 203 discovers the ONU 4 in step 402, the medium access control unit 203 receives the register request message from the ONU 4 to measure the round trip delay time between the OLT 2 and the ONU 4 (403).

  In step 403, the medium access control unit 203 synchronizes the times of the OLT 2 and the ONU 4 by transmitting a register message to the ONU 4. That is, by receiving the register message from the OLT 2, the ONU 4 holds the time when the OLT 2 transmits the downlink frame in the time counting circuit provided in itself as the time when the downlink frame transmitted from the OLT 2 is received.

  For this reason, in this embodiment, the time at which the OLT 2 transmits the downlink frame and the time at which the ONU 4 receives the downlink frame are the same at the OLT 2 and the ONU 4 due to the synchronization of the time between the OLT 2 and the ONU 4. On the other hand, the time when the OLT 2 receives the upstream frame is later than the time when the ONU 4 transmits the upstream frame by the time that the signal reciprocates between the OLT 2 and the ONU 4 (round-trip delay time).

  Note that the PON system of this embodiment synchronizes the time between the OLT 2 and the ONU 4 by transmitting and receiving time stamps between the OLT 2 and the ONU 4 in the same manner as the EPON defined in the IEEE 802.3 standard 64 chapter. . The time stamp is a counter value calculated by a time counting circuit provided in the OLT 2 and the ONU 4, and the time stamp value indicates the time.

  In step 403, the medium access control unit 203 of the OLT 2 transmits a Gate message to the ONU 4. The Gate message includes information indicating a time (time band) assigned to the ONU 4 for the ONU 4 to transmit an upstream frame, that is, a value stored in the time stamp management table 210.

  In addition, the medium access control unit 203 transmits the upstream frame by subtracting the round trip delay time measured in step 403 from the time allocated in advance to receive the upstream frame transmitted from the ONU 4. The time allocated to the ONU 4 is calculated.

  The medium access control unit 203 of the OLT 2 stores the round trip delay time of the ONU 4 measured in step 403 in the area 2102 of the time stamp management table 210 (404). After step 404, data requested by the user is transmitted / received between the OLT 2 and the ONU 4 (405).

  When the power-off notification is received from the battery 12, the EMS 8, or the ONU 4, the power monitoring unit 209 of the OLT 2 determines to start the transmission clock speed change process (406).

  After step 406, the transmission rate control unit 206 reads the transmission rate when the ONU 4 is abnormal from the transmission rate management table 207 (407). If the transmission rate management table 207 stores the transmission rates of a plurality of ONUs, the transmission rate control unit 206 reads the transmission rates of all ONUs in step 407.

  Then, the transmission rate control unit 206 determines the transmission clock rate at the time of abnormality based on the transmission rate of the ONU 4 read in step 407 or the sum of the transmission rates of all the ONUs read in step 407. (408).

  FIG. 5 is an explanatory diagram illustrating the transmission rate management table 207 according to the first embodiment of this invention.

  The transmission rate management table 207 includes a normal transmission rate of ONUs (including ONU4) connected to the OLT 2 and a transmission rate at the time of abnormality. Each value included in the transmission rate management table 207 is stored in advance by an administrator or a user. The transmission rate management table 207 includes an area 2071, an area 2072, and an area 2073.

  Area 2071 includes an identifier for uniquely identifying each ONU. The identifier stored in the area 2071 may be an LLID (Logical Link ID).

  A region 2072 includes an upper limit value of the normal transmission rate. An area 2073 includes an upper limit value of the transmission rate at the time of abnormality. The OLT 2 and each ONU must guarantee at least the bandwidth indicated by the area 2072 and the area 2073 in each of the normal state and the abnormal state.

  A transmission rate management table 207 shown in FIG. 5 shows transmission rates of five ONUs. Further, the transmission rate management table 207 shown in FIG. 5 indicates the transmission rate assigned to each ONU when the sum of the transmission rates at the time of a power failure for all ONUs is 4 Mbit / second.

  The transmission rate management table 207 may indicate the transmission rate of at least one ONU.

  Further, the transmission rate control unit 206 described above transmits a downlink transmission clock speed at the time of abnormal transmission (downlink transmission clock speed) and an abnormal transmission clock speed for transmission of an upstream frame (uplink transmission clock speed). ) And the same value. However, in step 408, the transmission rate control unit 206 of the present embodiment may set the downlink transmission clock rate and the uplink transmission clock rate to different values.

  When the downlink transmission clock speed at the time of abnormality and the uplink transmission clock speed at the time of abnormality are set to different values, the transmission speed management table 207 indicates the transmission speed of the upstream frame at the normal time and the abnormal time, The transmission rate of the downstream frame at the time of abnormality may be included.

  The method of the present embodiment used in step 408 can realize the transmission rate of the above-mentioned ONU 4 or the sum of the transmission rates among a plurality of values determined in advance as the transmission clock rate, and transmit the lowest value. In this method, the transmission speed control unit 206 selects a clock speed value. In this embodiment, there are four values determined as the transmission clock speed: 10 Gbit / second, 1 Gbit / second, 100 Mbit / second, and 10 Mbit / second. Then, the transmission speed control unit 206 determines the selected transmission clock speed as the transmission clock speed at the time of abnormality.

  In the example of the transmission rate shown in FIG. 5, the sum of the transmission rates at the time of failure is 4 Mbit / sec, a transmission rate of 4 Mbit / sec can be realized, and the lowest transmission clock rate is 10 Mbit / sec. Seconds. For this reason, the transmission rate control unit 206 determines 10 Mbit / sec as the transmission clock rate at the time of abnormality.

  The transmission rate control unit 206 sets the medium access control unit 203 to transmit a downstream frame or receive an upstream frame at the determined transmission clock rate at the time of abnormality. In the following, in the medium access control unit 203, the process of changing the transmission clock speed for transmitting the downlink frame to the transmission clock speed at the time of abnormality is referred to as a downlink clock change process in OLT2, and the uplink frame is received. The process of changing the transmission clock speed to the transmission clock speed at the time of abnormality will be referred to as an upstream clock change process in OLT2.

  In addition, a process in which the ONU changes the transmission clock speed at which the ONU transmits an upstream frame to the transmission clock speed at the time of abnormality is described as an upstream clock change process in the ONU. In addition, a process in which the ONU changes the transmission clock speed for receiving the downstream frame to the transmission clock speed at the time of abnormality is referred to as a downstream clock change process in the ONU.

  In general, it is known that a CMOS logic circuit consumes power proportional to a clock frequency. Therefore, by reducing the transmission clock speed of the medium access control unit 203 or the medium access control unit 303 using the CMOS logic circuit from, for example, 10 Gbit / second to 10 Mbit / second, the power consumption of about 1/1000 is achieved. Reduction is expected.

  After step 408, the bandwidth control unit 208 determines the timing for changing the transmission clock speed of the ONU 4. The determined change timing is stored in the time stamp management table 210 (409).

  FIG. 6 is an explanatory diagram illustrating the time stamp management table 210 according to the first embodiment of this invention.

  The time stamp management table 210 shown in FIG. 6 indicates the included values in decimal numbers. That is, the timing shown in FIG. 6 is indicated by a relative time from a predetermined reference time. The time stamp management table 210 includes areas 2101 to 2106.

  Area 2101 includes an identifier for uniquely identifying each ONU. The identifier stored in the area 2101 may be an LLID. The time stamp management table 210 includes at least one row related to the ONU or LLID.

  An area 2102 is a total value (round-trip delay time) from the time from when a signal is transmitted from the OLT 2 until each ONU receives the signal and the time from when the signal is transmitted from each ONU to when the OLT 2 receives the signal. ). A value is stored in the area 2102 in step 403 described above.

  An area 2103 indicates the time (time band) assigned to the OLT 2 for the OLT 2 to receive the upstream frame transmitted from each ONU. In this embodiment, a value is stored in advance in the area 2103.

  An area 2104 indicates the time (time band) assigned to each ONU in order for each ONU to transmit an upstream frame. The time indicated by the area 2104 is the time at which the upstream frame is transmitted from each ONU. Therefore, the value of the area 2104 corresponds to a value obtained by subtracting the value of the area 2102 from the value of the area 2103.

  An area 2105 indicates the time when the downlink clock change process is performed in the OLT 2 and the time when the downlink clock change process is performed in the ONU. An area 2106 indicates the time when the upstream clock change process is performed in the ONU.

  The time stamp management table 210 of the present embodiment indicates the time in the OLT 2 and the ONU by the time stamp used in the OLT 2 and the ONU. In the following description, the time stamps in the OLT 2 and the ONU are all expressed in decimal numbers.

  When the time stamp in the present embodiment corresponds to, for example, 16 nanoseconds per time stamp, the time width 0020 is 320 nanoseconds. At this time, the start time (time stamp 0010) and the end time (time stamp 0030) of the downlink clock change process shown in the area 2105 of the row 2107 in FIG. It includes the time required to change the speed (LENGTH: time width 0020).

  In step 409, the bandwidth control unit 208 first determines the start time and end time of the upstream clock change process in the OLT 2.

  Here, the bandwidth control unit 208 in the first embodiment performs the upstream clock change process in the OLT 2 so that the upstream clock change process in the OLT 2 is completed at the start time of the time band assigned to receive the upstream frame. Determine the start time and end time of the.

  For example, the bandwidth control unit 208 sets the start time (time stamp 0510) of the time band indicated by the area 2103 in the row 2107 shown in FIG. 6 as the end time (time stamp 0510) of the upstream clock change process in the OLT 2. Then, the result of subtracting the previously held time for changing the transmission clock speed (LENGTH) from the end time of the upstream clock change process in the OLT 2 is used as the start time (0490) of the upstream clock change process in the OLT 2. ).

  Band controller 208 previously holds a time (LENGTH) for changing the transmission clock speed. The OLT 2 and the ONU can perform the upstream clock change process in the OLT 2 and the ONU within the time indicated by the time LENGTH, and can perform the downstream clock change process in the OLT 2 and the ONU.

  Further, the bandwidth control unit 208 may hold in advance the time required for the uplink clock change process (uplink LENGTH) and the time required for the downlink clock change process (downlink LENGTH). The OLT 2 and the ONU can perform an upstream clock change process within the time indicated by the upstream LENGTH, and can perform a downstream clock change process within the time indicated by the downstream LENGTH.

  Further, the bandwidth control unit 208 determines the start time and end time of the upstream clock change process in the ONU 4 in step 409. Then, the start time and end time of the upstream clock change process in the ONU 4 are stored in the area 2106 of the row corresponding to the ONU 4 in the time stamp management table 210.

  Here, the bandwidth control unit 208 in the first embodiment determines the start time and end time of the upstream clock change process in the ONU 4 from the start time and end time of the upstream clock change process in the OLT 2 (corresponding to the area 2102). ) Is subtracted.

  For example, the bandwidth control unit 208 subtracts the round-trip delay time (time width 100) from the start time (time stamp 0490) and end time (time stamp 0510) of the upstream clock change process in the OLT 2 to thereby generate the upstream clock in the ONU 4. The change processing start time (time stamp 0390) and end time (time stamp 0410) are calculated.

  If an upstream frame is transmitted from the ONU 4 from the time stamp 0390 to the time stamp 0410 in the ONU 4, the OLT 2 receives the upstream frame from the time stamp 0490 to the time stamp 0510 in the OLT 2.

  Therefore, as described above, the timing of the upstream clock change process in the OLT 2 and the timing of the upstream clock change process in the ONU 4 are determined, and the upstream frame is not transmitted at the timing of the upstream clock change process in the OLT 2 and the ONU. It is possible to prevent the uplink frame from being lost in the OLT 2 when the uplink clock change process is performed.

  This is because ONU 4 can transmit an upstream frame at a transmission clock speed different from the transmission clock speed in OLT 2 when the timing of the upstream clock change process in OLT 2 is not delayed by the round-trip delay time from the timing of the upstream clock change process in ONU 4. It is because there is sex.

  When the bandwidth control unit 208 performs the process of FIG. 4 with a plurality of ONUs, the start time of the upstream clock change process in the OLT 2 is reciprocated to the start time of the upstream clock change process that is started earliest among all the ONUs. You may set to the time which added delay time. This is because in the present embodiment, the upstream clock change process in the OLT 2 only needs to be performed once.

  In step 409, the bandwidth control unit 208 determines the start time of the downlink clock change process in the OLT 2 and the ONU 4. Then, the determined time is stored in the area 2105 of the row corresponding to the ONU 4 of the time stamp management table 210 as the start time of the downlink clock change process.

  Here, the bandwidth control unit 208 according to the first embodiment, when a clock change notification described later reaches the ONU 4, and after the downstream clock change process in the ONU 4 is completed before the upstream clock change process in the ONU 4 is started, The start time of the downlink clock change process may be set to any value.

  Specifically, in step 409, the bandwidth control unit 208 sets the start time and end time of the downlink clock change process so that the downlink clock change process ends before the start time of the area 2106 of the time stamp management table 210. Determine. Further, when the processing in FIG. 4 is performed with a plurality of ONUs, the bandwidth control unit 208 sets the start time and the end time of the downlink clock change processing for all ONUs to the same time.

  Then, the bandwidth control unit 208 stores the determined start time and end time of the downlink clock change process in the area 2105 of the row corresponding to the ONU 4 of the time stamp management table 210.

  An area 2105 illustrated in FIG. 6 indicates that the start time of the downlink clock change process is the time stamp 0010 and the end time of the downlink clock change process is the time stamp 0030. Here, the time (LENGTH) for changing the transmission clock speed is a time width 0020.

  As described above, by determining the timing of the downlink clock change process in the OLT 2 and the timing of the downlink clock change process in the ONU 4, the downlink frame is lost in the ONU 4 when the downlink clock change process is performed in the ONU 4. Can be prevented. This is because if the timing of the downstream clock change process in the OLT 2 is different from the timing of the downstream clock change process in the ONU 4, the OLT 2 may transmit a downstream frame at a transmission clock speed different from the transmission clock speed in the ONU 4. is there.

  After step 409, the transmission rate notification unit 205 of the OLT 2 transmits a clock change notification to the ONU 4 (410). The clock change notification includes the transmission clock speed at the time of abnormality determined in step 408, the start time indicated by the area 2105 and the area 2106, determined in step 409, and the like.

  When the OLT 2 performs the processing shown in FIG. 4 with a plurality of ONUs, the clock change notification is transmitted to the plurality of ONUs.

  FIG. 7 is an explanatory diagram illustrating a format of a clock change notification according to the first embodiment of this invention.

  The format of the clock change notification according to this embodiment conforms to the format of the GATE message that is a signal transmission permission message defined in Chapter 64 of the IEEE 802.3 standard. The format of the clock change notification according to the present embodiment may be transmitted periodically according to a predetermined cycle, or may be transmitted only when the transmission clock speed is changed during a power failure.

  The clock change notification includes areas 701 to 715. An area 701 includes a preamble, an area 702 includes a transmission flag, and an area 703 includes an LLID. The area 704 includes a destination MAC address, that is, the MAC address of the ONU 4. An area 705 includes a source MAC address, that is, the MAC address of the OLT 2. Region 706 contains the type, region 707 contains the message ID, and region 708 contains the corresponding LLID.

  Area 709 includes the downstream transmission clock speed. An area 710 includes a start time of the downlink clock change process, and an area 711 includes a time required for the downlink clock change process (downlink LENGTH).

  Further, the area 712 includes the upstream transmission clock speed, the area 713 includes the start time of the upstream clock change process, and the area 714 includes the time required for the upstream clock change process (upstream LENGTH). An area 715 includes padding, and an area 716 includes an FCS (Frame Check Sequence).

  Further, the clock change notification according to the present embodiment may include a plurality of areas 708 to 712 for each LLID indicated by the area 708. As a result, information on the areas 709 to 712 regarding different LLIDs can be transmitted simultaneously from the OLT 2.

  Further, the area 711 and the area 714 illustrated in FIG. 7 may include the end time of the downlink clock change process in the ONU 4 and the end time of the uplink clock change process in the ONU 4 instead of the downlink LENGTH and the uplink LENGTH. Further, the value of the area 709 and the value of the area 712 may be the same value.

  Area 709 and area 712 shown in FIG. 7 include the transmission clock speed at the time of abnormality determined in step 408 shown in FIG. In the above example, the transmission clock speed at the time of abnormality is 10 Mbit / sec.

  An area 710 includes the start time of the downlink clock change process indicated by the area 2105 of the time stamp management table 210. In the above-described example, the start time of the downstream clock change process is the time stamp 0010.

  Further, both the area 711 and the area 714 may include the time (LENGTH) used in step 409 for changing the transmission clock speed. In the above example, the time (LENGTH) for changing the transmission clock speed is the time width 0020.

  The area 713 includes the start time of the upstream clock change process in the ONU 4 indicated by the area 2106 of the time stamp management table 210. In the above example, the start time of the upstream clock change process in the ONU 4 is the time stamp 0390.

  After step 410, the signal transmission / reception unit 201 of the OLT 2 transmits a Pause signal to the upper network 1 in accordance with an instruction from the transmission rate control unit 206 (411).

  Specifically, in step 411, the transmission rate control unit 206 acquires the start time and end time of the downlink clock change process from the area 2105 of the time stamp management table 210 via the control unit 204. Then, the transmission rate control unit 206 transmits a pause signal including an instruction for the upper network 1 to accumulate the downlink frame so that the OLT 2 does not receive the downlink frame from the start time to the end time of the downlink clock change process. 201 to transmit.

  Note that a Pause signal defined in the IEEE 802.3 standard Annex 31B chapter is used as a Pause signal and a Pause release signal described later in this embodiment. The Pause signal and Pause release signal may be transmitted to the higher level network 1 as long as the OLT 2 does not receive the downlink frame from the start time to the end time of the downlink clock change process.

  For example, the transmission rate control unit 206 determines in advance the signal processing time from when the Pause signal is transmitted to the upper network 1 until the Pause signal is processed by the upper network 1 and no downstream frame is received from the upper network 1. You may get it. Then, the transmission rate control unit 206 may transmit the Pause signal to the ONU 4 at a time obtained by subtracting the signal processing time from the start time of the downlink clock change process.

  Further, for example, the transmission rate control unit 206 transmits the start time of the downlink clock change process to the upper network 1, and causes the upper network 1 to accumulate the downstream frame so that the downstream frame does not reach the OLT 2 from the start time in the OLT 2. May be.

  Hereinafter, the start time of the downlink clock change process in the OLT 2 will be described as time T1, the start time of the downlink clock change process in the ONU will be described as time T3, and the end time of the downlink clock change process in the OLT 2 will be indicated as time T5. It describes. In the first embodiment, time T1 is the same as time T3.

  The start time of the upstream clock change process in the ONU is described as time T2, the start time of the upstream clock change process in the OLT 2 is described as time T4, and the end time of the upstream clock change process in the ONU is defined as time T6. Describe. In the first embodiment, time T4 is the time obtained by adding the round trip delay time between the OLT 2 and the ONU to the time T2.

  After step 411, the transmission rate control unit 206 instructs the medium access control unit 203 to start the process of changing the transmission clock rate at the time of transmitting the downlink frame from the time T1 (412). Thereby, the downlink clock change process in the OLT 2 is started. In the example shown in FIG. 6, the time T1 is the time stamp 0010.

  After step 412, the signal transmitting / receiving unit 201 transmits a pause release signal to the upper network 1 in accordance with an instruction from the transmission rate control unit 206 (413). The Pause release signal includes content that permits the higher-level network 1 to transmit a downstream frame to the OLT 2 so that the OLT 2 can receive the downstream frame from time T5. Similarly to the Pause signal, the Pause cancellation signal may be transmitted by any method as long as the OLT 2 can receive the downstream frame from time T5.

  By steps 411 and 413, the upper network 1 accumulates the downstream frames so that the OLT 2 does not receive the downstream frames until the start time and the end time of the downstream clock change process in the OLT 2. For this reason, since the medium access control unit 203 is performing the downlink clock change process, it is possible to prevent the downlink frame from being lost because the downlink frame cannot be processed.

  After step 413, the transmission rate control unit 206 instructs the medium access control unit 203 to start the process of changing the transmission clock rate when receiving the uplink frame from time T4 (414). Thereby, the upstream clock change process in the OLT 2 is started.

  In the example shown in FIG. 6, the time T4 is a time obtained by adding the round trip delay time to the start time T2 of the upstream clock change process of the ONU (line 2107) having the earliest time to start the upstream clock change process. That is, in the example shown in FIG. 6, the time T4 is a time stamp 0049.

  Note that the transmission rate control unit 206 in the first embodiment only needs to perform the processing of step 411 to step 414 only once when performing the processing of FIG. 4 with a plurality of ONUs.

  After step 414, the OLT 2 ends the process shown in FIG.

  FIG. 8 is a flowchart illustrating a process of synchronizing the transmission clock speed by the ONU 4 according to the first embodiment of this invention.

In the following, a process in which the ONU 4 synchronizes the transmission clock speed with the OLT 2 will be described. All ONUs connected to the OLT 2 perform the same processing as that shown in FIG. Steps 502 to 505 shown in FIG. 8 are executed periodically or at a timing designated by the user or the like when the OLT 2 and the ONU 4 are supplied with normal power. The medium access control unit 303 of the ONU 4 Receives a discovery instruction from the OLT 2 as defined in Chapter 64 of the IEEE 802.3 standard (502). After step 502, the medium access control unit 303 of the ONU 4 transmits a register request message to cause the OLT 2 to measure the round trip delay time (503).

  After step 503, the medium access control unit 303 of the ONU 4 receives the GATE message from the OLT 2, thereby receiving information indicating the time band assigned to the ONU 4 for transmitting the upstream frame (504). Further, the medium access control unit 303 of the ONU 4 synchronizes the time between the OLT 2 and the time counting circuit included in the ONU 4 itself by receiving a register message from the OLT 2 after step 503.

  The ONU 4 transmits the uplink frame received from the terminal device 6 to the OLT 2 based on the information received in step 504 (505).

  When the OLT 2 receives the power-off notification from the battery 12 or the EMS 8, the transmission rate notification reception unit 306 receives the clock change notification transmitted by the OLT 2 in step 410 of FIG. 4 from the OLT 2 (509).

  In step 509, the transmission rate notification receiving unit 306 includes the start time (time T3) and end time (time T3 + LENGTH) of the downstream clock change process in the ONU 4 and the upstream clock change process in the ONU 4 included in the received clock change notification. The start time (time T2) and the end time (time T6 = time T2 + LENGTH) are stored in the time stamp management table 308 via the control unit 304.

  After step 509, the transmission rate control unit 307 acquires the time T3 from the time stamp management table 308, and instructs the medium access control unit 303 to start the downlink clock change process from time T3 (510). Thereby, the downstream clock change process in the ONU 4 is executed.

  After step 510, the electrical transmission / reception unit 301 transmits a Pause signal to the terminal device 6 in accordance with an instruction from the transmission rate control unit 307 (512).

  Specifically, in step 512, the transmission rate control unit 307 acquires the start time and end time of the upstream clock change process in the ONU 4 from the time stamp management table 308. Then, the transmission rate control unit 206 transmits a pause signal including an instruction for the terminal device 6 to accumulate the upstream frame so that the ONU 4 does not receive the upstream frame from the start time to the end time of the upstream clock change process in the ONU 4. It is made to transmit to the electric side transmission / reception part 301. FIG.

  The method of transmitting a Pause signal and a Pause cancellation signal described later to the terminal device 6 is the same as the method of Step 411 and Step 413 described above, except that the transmission destination is the terminal device 6. Further, the Pause signal and the Pause release signal to be described later may be transmitted to the terminal device 6 as long as the ONU 4 does not receive the upstream frame from the start time to the end time of the upstream clock change process.

  After step 512, the transmission rate control unit 307 acquires the time T2 from the time stamp management table 308, and instructs the medium access control unit 303 to start the uplink clock change process from time T2 (513). Thereby, the upstream clock change process in the ONU 4 is executed.

  After step 513, the electrical transmission / reception unit 301 transmits a pause release signal to the terminal device 6 in accordance with an instruction from the transmission rate control unit 307 (517). The Pause cancellation signal includes contents permitting the terminal device 6 to transmit the upstream frame to the ONU 4 so that the ONU 4 can receive the upstream frame from time T6. Similarly to the Pause signal, the Pause cancellation signal may be transmitted by any method as long as the ONU 4 can receive the upstream frame from time T6.

  In step 512 and step 517, the terminal device 6 accumulates in the terminal device 6 an uplink frame to be transmitted to the ONU 4 from the start time to the end time of the uplink clock change process in the ONU 4. For this reason, since the medium access control unit 303 is performing the upstream clock change process, it is possible to avoid the upstream frame from being processed and the upstream frame from being lost.

  FIG. 9 is a sequence diagram illustrating a synchronization process of the transmission clock speed according to the first embodiment of this invention.

  A sequence 901 to a sequence 904 are ONU registration and communication start sequences defined in the IEEE 802.3 standard 64 chapter. By the sequence 901 to the sequence 904, the OLT 2 can measure the round trip delay time between the OLT 2 and the ONU. Further, the OLT 2 can transmit to the ONU a band in which the ONU transmits an upstream frame to the OLT 2.

  A sequence 901 indicates a discovery instruction, a sequence 902 indicates a register request, a sequence 903 indicates a register message and a Gate message, and a sequence 904 indicates a register ACK message. A sequence 905 indicates data communication. Sequence 901 to sequence 905 correspond to step 402 to step 405 shown in FIG. 4 and step 502 to step 505 shown in FIG.

  The battery 12 transmits a power-off notification to the OLT 2 (906). The sequence 906 corresponds to step 406 shown in FIG.

  After the sequence 906, the OLT 2 transmits a clock change notification corresponding to step 410 in FIG. 4 to the ONU 4 to notify the start time of the downstream clock change process and the upstream clock change process in the ONU 4 (908). The sequence 908 corresponds to step 410 shown in FIG. 4 and step 509 shown in FIG.

  After the sequence 908, the OLT 2 transmits a Pause signal to the upper network 1 (911). The sequence 911 corresponds to step 411 in FIG.

  After sequence 911, from time T1 to time T5, OLT 2 performs downlink clock change processing. Further, the ONU 4 performs a downlink clock change process between the time T3 and LENGTH.

  The OLT 2 transmits a Pause release signal corresponding to Step 413 in FIG. 4 to the upper network 1 before time T5 (912). As a result, the OLT 2 can receive the downstream frame from the upper network 1 after the time T5.

  After the downlink clock change process in the OLT 2, the OLT 2 transmits the downlink frame to the ONU 4 at the transmission clock speed at the time of abnormality.

  After the downlink clock change process in the ONU 4, that is, after the time T3 + LENGTH, the ONU 4 transmits a Pause signal corresponding to step 512 shown in FIG. 8 to the terminal device 6 (913).

  After the sequence 913, the ONU 4 performs an upstream clock change process from time T2 to time T6. Further, from time T4 to LENGTH, the OLT 2 performs an upstream clock change process in the OLT 2.

  Prior to time T6, the ONU 4 transmits a Pause release signal corresponding to step 517 of FIG. 8 to the terminal device 6 (914). Thereby, the ONU 4 can receive the uplink frame from the terminal device 6 after the time T6.

  As described above, the transmission clock speeds in the OLT 2 and the ONU 4 are synchronized.

  In the sequence 908 in FIG. 9 (corresponding to step 410 shown in FIG. 4), the processing when the clock change notification does not arrive at the ONU due to a network failure or the like will be described below.

  When the clock change notification cannot be transmitted in the sequence 908, the OLT 2 performs the downlink clock change process from the time T1 to the time T5, and then transmits the downlink frame at the changed transmission clock speed (transmission clock speed at the time of abnormality). The ONU 4 determines whether or not the transmission rate of the downstream frame transmitted from the OLT 2 corresponds to the transmission clock rate in the ONU 4 for receiving the downstream frame.

  Then, when the transmission rate of the received downlink frame does not correspond to the transmission rate of the ONU 4, the ONU 4 determines the transmission clock rate at the time of abnormality according to the transmission rate of the received downlink frame. Then, the downstream clock change process in the ONU 4 is performed using the determined transmission clock speed at the time of abnormality.

  Here, the ONU 4 does not need to perform the downlink clock change process at time T3, and may perform the downlink clock change process when receiving the downlink frame.

  On the other hand, when the transmission rate of the received downlink frame does not correspond to the transmission rate in the ONU 4, the ONU 4 executes the uplink clock change process using the determined transmission clock rate at the time of abnormality.

  Further, the ONU 4 may hold in advance the transmission clock speed at the time of abnormality when the upstream clock change process is performed without receiving the clock change notification. Then, the upstream clock change process may be performed using the transmission clock speed at the time of abnormality held in advance.

  Here, when the clock change notification is not transmitted from the OLT 2, the ONU 4 does not need to perform the uplink clock change process at the time T2, and may start the uplink clock change process when the downlink frame is received from the OLT 2.

  Further, when the clock change notification cannot be transmitted, the OLT 2 performs the upstream clock change process using the transmission clock speed at the time of abnormality after the round-trip delay time after completing the downstream clock change process. Thereby, the upstream clock change process in the ONU 4 and the upstream clock change process in the OLT 2 can be synchronized.

  The OLT 2 may also hold in advance the transmission clock speed at the time of abnormality when the clock change notification cannot be transmitted. Then, the upstream clock change process may be performed using the transmission clock speed at the time of abnormality held in advance.

  According to the first embodiment, even when the clock change notification cannot be transmitted, the downlink clock change process is performed regardless of the time T2, the time T3, the time T4, and the LENGTH by using the method described above. And the upstream clock change process can be executed sequentially. The transmission clock speed can be changed more reliably.

  According to the first embodiment, when the power is not stably supplied, the transmission clock speed for the OLT 2 and the ONU to transmit the upstream frame or the downstream frame can be changed. As a result, power consumption in the OLT 2 and the ONU is reduced.

  In addition, when changing the transmission clock speed, the upstream frame is stored in the terminal device 6 using the Pause signal, and the downstream frame is stored in the upper network 1, thereby preventing the loss of the upstream frame and downstream frame in the OLT 2 and the ONU. be able to.

  Further, by executing the downlink clock change process in the OLT 2 and the ONU at a time synchronized between the OLT 2 and the ONU, it is possible to minimize the state in which the downlink transmission clock speed differs between the OLT 2 and the ONU. By executing the upstream clock change process in the OLT 2 after the round-trip delay time from the upstream clock change process in the ONU, it is possible to minimize the state in which the upstream transmission clock speed differs between the OLT 2 and the ONU.

  In the first embodiment, after the OLT 2 changes the transmission clock rate of the downstream frame, the transmission clock rate of the upstream frame in the OLT 2 and the ONU is changed. Then, the change of the transmission clock speed of the upstream frame by the ONU is completed before the ONU transmits the upstream frame in the allocated band.

  Thereby, the OLT 2 and the ONU according to the first embodiment can reliably execute the downlink clock change process and the uplink clock change process before the band allocated for the ONU to transmit the uplink frame. That is, even in an irregular case where a clock change notification does not reach due to a transmission error or the like, the upstream clock change process in the ONU is performed after the downlink clock change process in the OLT 2 is completed until the band for transmitting the upstream frame. It can be carried out. For this reason, the transmission clock speed can be changed stably.

(Second Embodiment)
The second embodiment is an embodiment in which the ONU simultaneously performs the downlink clock change process and the uplink clock change process in the ONU.

  The OLT 2 and the ONU (including ONU 4 and ONU 5) in the second embodiment have the same processing units as the OLT 2 and the ONU 4 in the first embodiment.

  FIG. 10 is a flowchart illustrating a process of synchronizing the transmission clock speed by the OLT 2 according to the second embodiment of this invention.

  FIG. 10 shows a process in which the OLT 2 synchronizes the transmission clock speed with the ONU 4 as in FIG. However, the process illustrated in FIG. 4 may be performed by the OLT 2 and a plurality of ONUs.

  Steps 402 to 405 shown in FIG. 10 are the same as steps 402 to 405 shown in FIG. From Step 402 to Step 403, the ONU 4 holds the time when the OLT 2 transmits the downlink frame as the time when the downlink frame transmitted from the OLT 2 is received. In step 403, the OLT 2 measures the round trip delay time between the OLT 2 and the ONU 4.

  If a power-off notification is received from the ONU 4 after step 405, the power monitoring unit 209 of the OLT 2 determines to start transmission clock rate change processing (420). In step 420, the power monitoring unit 209 may determine to start the transmission clock speed changing process even when the power-off notification is received from the battery 12 or the EMS 8.

  After step 420, the transmission rate control unit 206 determines the transmission clock rate at the time of abnormality as in steps 407 and 408 shown in FIG. 4 (407, 408).

  After step 408, the bandwidth control unit 208 starts and ends the downstream clock change process in the OLT 2, starts and ends the upstream clock change process in the OLT 2, starts and ends the downstream clock change process in the ONU 4, Then, the start time and end time of the upstream clock change process in the ONU 4 are determined. Then, the determined start time and end time are stored in the row corresponding to ONU 4 of the time stamp management table 210 (421).

  FIG. 11 is an explanatory diagram illustrating a time stamp management table 210 according to the second embodiment of this invention.

  The time stamp management table 210 of the second embodiment is similar to the time stamp management table 210 of the first embodiment, but the values stored in the area 2105 are different.

  The bandwidth control unit 208 of the second embodiment uses the same method as the method of determining the start time and end time of the uplink clock change process in the OLT 2 in the first embodiment to start the uplink clock change process in the OLT 2 and the ONU 4. And determine the end time.

  On the other hand, in step 421, the bandwidth control unit 208 of the second embodiment determines the start time and end time of the upstream clock change process in the ONU 4 as the start time and end time of the downstream clock change process in the OLT 2 and ONU 4. . For this reason, the value of the area 2105 and the value of the area 2106 of the time stamp management table 210 of the second embodiment are the same value.

  When the OLT 2 performs the processing shown in FIG. 10 with a plurality of ONUs, the start time and end time of the downlink clock change processing in the OLT 2 are different for each ONU. For this reason, the transmission rate control unit 206 of the OLT 2 may perform the downlink clock change process only in the first time band among the time bands indicated by the area 2105. Then, only the Pause signal and the Pause release signal may be transmitted in the second time band in the time band indicated by the area 2105.

  This is because the OLT 2 of the present embodiment can change the downlink transmission clock speed for transmission to all ONUs once the downlink clock change process is performed.

  For example, the time T1 in the second embodiment is the time stamp 0390 that is the earliest time of the downlink clock change process in the time stamp management table 210 of FIG. Time T5 is a time stamp 0410.

  The time T4 in the second embodiment is a time stamp 0490 that is the earliest time of the upstream clock change process. The time T3 and the time T2 in the second embodiment are the same value and are the time stamp 0390.

After step 421, the transmission rate notification unit 205 transmits a clock change notification to the ONU 4 as in the first embodiment (410). Further, as in the first embodiment, the signal transmitting / receiving unit 201 transmits a Pause signal to the upper network 1 in accordance with the instruction of the transmission rate control unit 206 (411).
After step 411, the transmission rate control unit 206 causes the medium access control unit 203 to start downlink clock change processing in the OLT 2 at time T1 (412). After step 412, the transmission rate control unit 206 causes the medium access control unit 203 to start the uplink clock change process in the OLT 2 at time T4 (414).

  After step 414, the signal transmission / reception unit 201 transmits a pause release signal to the upper network 1 in accordance with the instruction from the transmission rate control unit 206, as in step 413 of the first embodiment (413).

  When the OLT 2 performs the processing shown in FIG. 10 with a plurality of ONUs, the transmission rate control unit 206 performs Step 411, Step 412, Step 414, and Step 413 for each row of the time stamp management table 210. In this case, the transmission rate control unit 206 may not perform Step 412 and Step 414 that are performed for the second time. Further, Step 411, Step 412, Step 414, and Step 413 may be performed in parallel on the ONU indicated by each row.

  Also, the transmission rate control unit 206 determines whether or not the end time included in the area 2105 of the time stamp management table 210 is included in the time band for performing the downlink clock change process indicated by another row. In step 413, the Pause release signal need not be transmitted. Accordingly, for example, when the time bands for performing the downlink clock change processing overlap as shown in the row 2108 and the row 2109 shown in FIG. It is possible to prevent the release signal from being transmitted and the downstream frame from being transmitted to the OLT 2.

  After executing step 413 for all the rows of the time stamp management table 210, the OLT 2 ends the processing shown in FIG.

  FIG. 12 is a flowchart illustrating a process of synchronizing the transmission clock speed by the ONU 4 according to the second embodiment of this invention.

  All ONUs connected to the OLT 2 of the second embodiment perform the same processing as the processing shown in FIG. Steps 502 to 505 shown in FIG. 12 are the same as steps 502 to 505 shown in FIG.

  After step 505, when the power monitoring unit 309 of the ONU 4 receives the power-off notification (506), the power monitoring unit 309 transmits the power-off notification to the OLT 2 via the medium access control unit 303 (507). A Dying Gasp message defined in IEEE Standard 572.3 Chapter 57 may be applied to the message for power-off notification in step 507.

  After step 507, the transmission rate notification receiving unit 306 receives the clock change notification as in the first embodiment (509).

  Here, the time T3 for starting the downstream clock change process (510) in the ONU 4 and the time T2 for starting the upstream clock change process (513) in the ONU 4 are the same. Therefore, the transmission rate control unit 307 transmits a Pause signal to the terminal device 6 before step 510 and step 513 (512).

  The order of step 512, step 510, and step 513 in the second embodiment described above is different from the order in the first embodiment (step 510, step 512, and step 513). However, the contents of the processing of step 512, step 510, and step 513 of the second embodiment are the same as the processing of step 512, step 510, and step 513 of the first embodiment.

  Then, after step 513 of the second embodiment, the transmission rate control unit 307 starts the transmission of the upstream frame after the end time of the upstream clock changing process in the ONU 4, The Pause release signal is sent to the terminal device 6 (517).

  FIG. 13 is a sequence diagram illustrating processing for changing the transmission clock speed according to the second embodiment of this invention.

  A sequence 901 to a sequence 905 illustrated in FIG. 13 are the same as the sequence 901 to the sequence 905 illustrated in FIG. 9.

  When it is detected that the power supplied from the power transmission network 10 has decreased or stopped, the battery 13 transmits a power-off notification to the ONU 4 (920). The sequence 920 corresponds to step 506 in FIG.

  When receiving the power-off notification from the battery 13, the ONU 4 determines that the power-off has been detected, and transmits the power-off notification to the OLT 2 (921). The sequence 921 corresponds to step 507 in FIG. 12 and step 420 in FIG.

  After the sequence 921, the OLT 2 transmits a clock change notification to the ONU 4 as in the sequence 908 shown in FIG. 9 (908). The sequence 908 corresponds to step 410 in FIG. 10 and step 509 in FIG.

  After transmitting the Pause signal to the terminal device 6 in the sequence 913, the ONU 4 starts the upstream clock changing process and the downstream clock changing process in the ONU 4 at the same time (time T2 and time T3). Then, after the uplink clock change process, a Pause cancellation signal is transmitted to the terminal device 6 so that an uplink frame can be received (sequence 914).

  Similar to the sequence 911 and sequence 912 shown in FIG. 9, the OLT 2 transmits a Pause signal and a Pause release signal to the upper network 1 so as not to receive the downstream frame from the upper network 1 from the time T1 to the time T5 (911). When the OLT 2 synchronizes the transmission clock speed with a plurality of ONUs, the sequence 911 and the sequence 912 of the second embodiment are repeated by the number of ONUs.

  Further, the OLT 2 executes the downstream clock change process in the OLT 2 at the same time T1 as the time T3 in the ONU 4. Then, at time T4 obtained by adding the round trip delay time to time T2 in the ONU 4, the upstream clock change process in the OLT 2 is executed.

  When performing transmission clock speeds with a plurality of ONUs, the OLT 2 of the present embodiment needs to stop the downstream frame while each ONU is performing the downstream clock change process. However, in the second embodiment, the downlink clock change processing in each ONU is performed at different times. Therefore, the time for the OLT 2 of the second embodiment to accumulate the downlink frame in the upper network 1 is the same as that in the first embodiment. It is longer than the time for the OLT 2 to accumulate the downstream frame in the upper network 1.

  However, since the ONU of the second embodiment performs the downlink clock change process and the uplink clock change process at the same time, each ONU only needs to hold the time T3 or the time T2, and waits for the change of the transmission clock speed. One process is sufficient. For this reason, processing in the ONU is simplified, and power consumption in the ONU can be reduced.

(Third embodiment)
The OLT 2 in the third embodiment simultaneously performs the downlink clock change process and the uplink clock change process.

  The OLT 2 and the ONU in the third embodiment have the same processing unit as the OLT 2 and the ONU in the first embodiment.

  FIG. 14 is a flowchart illustrating a process of synchronizing the transmission clock speed by the OLT 2 according to the third embodiment of this invention.

  FIG. 14 shows a process in which the OLT 2 synchronizes the transmission clock speed with the ONU 4 as in FIG. However, the process illustrated in FIG. 4 may be performed by the OLT 2 and a plurality of ONUs.

  Steps 402 to 408 shown in FIG. 14 are the same as steps 402 to 408 shown in FIG.

  After step 408, the bandwidth control unit 208 starts and ends the downstream clock change process in the OLT 2, starts and ends the upstream clock change process in the OLT 2, starts and ends the downstream clock change process in the ONU 4, Then, the start time and end time of the upstream clock change process in the ONU 4 are determined. Then, the determined start time and end time are stored in the time stamp management table 210 (422).

  FIG. 15 is an explanatory diagram illustrating a time stamp management table 210 according to the third embodiment of this invention.

  The time stamp management table 210 of the third embodiment is the same as the time stamp management table 210 of the first embodiment, but the values stored in the area 2105 and the area 2106 are different.

  The difference between the process shown in FIG. 4 and the process shown in FIG. 14 is that the downlink clock change process and the uplink clock change process are simultaneously performed in the OLT 2. Therefore, in step 422, the bandwidth control unit 208 determines the start time stored in the area 2103 in the row indicating the ONU 4 in the time stamp management table 210 as the end time of the upstream clock change process in the OLT 2. Also, the time obtained by subtracting LENGTH from the start time stored in the area 2103 of the row indicating ONU 4 is determined as the start time of the upstream clock change process in OLT 2.

  Here, when the OLT 2 performs the processing shown in FIG. 14 with a plurality of ONUs, the bandwidth control unit 208 extracts a row indicating the ONU assigned the earliest bandwidth for transmitting the uplink frame in step 422. The start time stored in the extracted row area 2103 is determined as the end time of the upstream clock change process in the OLT 2.

  Then, the bandwidth control unit 208 determines the start time and end time of the upstream clock change process in the OLT 2 as the start time and end time of the downstream clock change process in the OLT 2 and the ONU 4. Further, the time obtained by subtracting the round trip delay time indicated by the area 2102 from the start time and end time of the uplink clock change process in the OLT 2 is determined as the start time and end time of the uplink clock change process in the ONU 4.

  Then, the bandwidth control unit 208 stores the determined start time and end time in the area 2105 and the area 2106 in the row corresponding to the ONU 4 in the time stamp management table 210.

  Here, when the OLT 2 performs the processing shown in FIG. 14 with a plurality of ONUs, the bandwidth control unit 208 uses the time stamp management table to indicate the start time and end time of the downlink clock change processing in the OLT 2 determined by the above-described method. The data is stored in all the rows in the area 2105 of 210. This is because the downlink transmission clock speed is changed if the downlink clock changing process in the OLT 2 is performed only once.

  For example, in the row 2110 and the row 2111 of the time stamp management table 210 shown in FIG. 15, the time T1 is the time stamp 0490, and the time T4 is also the time stamp 0490. The time T3 indicated by the row 2110 is a time stamp 0490, and the time T2 is a time stamp 0390. The time T3 indicated by the row 2111 is a time stamp 0490, and the time T2 is a time stamp 0290.

  In the third embodiment, the upstream clock change process in the ONU 4 is performed before the downstream clock change process in the ONU 4.

  After step 422, the transmission rate notification unit 205 and the transmission rate control unit 206 of the OLT 2 execute step 410 and step 411 shown in FIG. Step 410 and step 411 shown in FIG. 14 are the same as step 410 and step 411 shown in FIG.

  After step 411, the transmission rate control unit 206 of the OLT 2 causes the medium access control unit 203 to start the downlink clock change process and the uplink clock change process in the OLT 2 at time T1 (that is, time T4) (423). Further, after Step 423, a Pause release signal is transmitted to the upper network 1 so that the downstream frame transmitted by the upper network 1 can be received from time T5 (= time T4 + LENGTH) (413).

  FIG. 16 is a flowchart illustrating a process of synchronizing the transmission clock speed by the ONU 4 according to the third embodiment of this invention.

  Steps 502 to 505 and 509 shown in FIG. 16 are the same as steps 502 to 505 and 509 shown in FIG.

  In the third embodiment, the upstream clock change process in the ONU 4 is also performed at an earlier time than the downstream clock change process in the ONU 4. For this reason, after step 509, the transmission rate control unit 307 of the ONU 4 transmits a Pause signal to the terminal device 6 via the electrical transmission / reception unit 301 so that the ONU 4 does not receive an upstream frame from time T2 (512). .

  After step 512, the transmission rate control unit 307 causes the medium access control unit 303 to perform uplink clock change processing in the ONU 4 at time T2 (513). After the step 513, when the upstream clock change process ends earlier than the time T3, the transmission rate control unit 307 sets the electrical transmission / reception unit 301 so that the ONU 4 can receive the upstream frame from the time T6 (= time T2 + LENGTH). Then, a Pause release signal is transmitted to the terminal device 6 (517).

  After step 517, the transmission rate control unit 307 performs downlink clock change processing at time T3 (510). After step 510, the ONU ends the process shown in FIG.

  FIG. 17 is a sequence diagram illustrating a transmission clock speed synchronization process according to the third embodiment of this invention.

  A sequence 901 to a sequence 906 and a sequence 908 illustrated in FIG. 17 are the same as the sequence 901 to the sequence 906 and the sequence 908 illustrated in FIG. 9.

  After transmitting the Pause signal in the sequence 911, the OLT 2 starts the uplink clock change process and the downlink clock change process simultaneously. Then, a Pause cancellation signal is transmitted to the upper network 1 so that the downstream frame can be received after the downstream clock changing process is completed (912).

  The ONU 4 transmits a Pause signal to the terminal device 6 so as not to receive an upstream frame from time T2. Then, the ONU 4 performs an upstream clock change process in the ONU 4 at a time T2, which is a time obtained by subtracting the round trip delay time from the time T4. Further, the ONU 4 transmits a Pause cancellation signal to the terminal device 6 so that the uplink frame transmitted from the terminal device 6 can be received from time T2.

  Further, the ONU 4 performs a downlink clock change process in the ONU 4 at time T3, which is the same time as time T1.

  In the third embodiment, the OLT 2 performs the downlink clock change process and the uplink clock change process in the OLT 2 at the same time for all ONUs. This eliminates the need for the OLT 2 to perform an upstream clock change process after waiting for time T4, and simplifies the processing or mounting in the OLT 2. And the power consumption in OLT2 reduces.

  Further, the downlink clock change process and the uplink clock change process in the OLT 2 are performed at the same time, and the process in each ONU is matched with the process in the OLT 2. It is possible to minimize the accumulation time.

  According to the present embodiment, when the power is not stably supplied, the transmission clock speed for the OLT 2 and the ONU to transmit the upstream frame or the downstream frame can be changed. As a result, power consumption in the OLT 2 and the ONU is reduced.

  In addition, when changing the transmission clock speed, the upstream frame is stored in the terminal device 6 using the Pause signal, and the downstream frame is stored in the upper network 1, thereby preventing the loss of the upstream frame and downstream frame in the OLT 2 and the ONU. be able to.

  Further, by executing the downlink clock change process in the OLT 2 and the ONU at a time synchronized between the OLT 2 and the ONU, it is possible to minimize the state in which the downlink transmission clock speed differs between the OLT 2 and the ONU. By executing the upstream clock change process in the OLT 2 after the round-trip delay time from the upstream clock change process in the ONU, it is possible to minimize the state in which the upstream transmission clock speed differs between the OLT 2 and the ONU.

  In addition, although the above-mentioned embodiment was described based on EPON prescribed | regulated to IEEE802.3 standard, PON using other transmission rates, ITU-T recommendation G., and others. GPON specified in the 984 series or ITU-T recommendation G. Even based on XGPON defined in the 987 series, it can be easily mounted.

1 Upper network 2 OLT
3 Optical splitter 4 ONU
5 ONU
6 Terminal device 7 Terminal device 8 EMS
DESCRIPTION OF SYMBOLS 10 Power transmission network 11 Power transmission network management system 12 Battery 13 Battery 14 Battery 201 Signal transmission / reception part 202 Electro-optical conversion part 203 Medium access control part 204 Control part 205 Transmission speed notification part 206 Transmission speed control part 207 Transmission speed management table 208 Band control part 209 Power monitoring unit 210 Time stamp management table 211 Power supply circuit 301 Electric side transmission / reception unit 302 Electro-optical conversion unit 303 Medium access control unit 304 Control unit 306 Transmission rate notification reception unit 307 Transmission rate control unit 308 Time stamp management table 309 Power monitoring unit 310 Power supply circuit

Claims (18)

An optical system comprising an optical line device for transmitting a signal and an optical network device for receiving a signal from the optical line device,
The optical line device is:
Transmission rate information indicating a minimum rate of a signal transmitted and received between the optical line device and the optical network device;
A power monitoring unit that acquires abnormality information indicating that power is not normally supplied to the optical line device or the optical network device;
When abnormality information is acquired by the power monitoring unit, based on the transmission rate information, a first downlink clock rate for the optical line device to transmit a downlink signal to the optical network device, and the optical network device A first speed controller for determining a first upstream clock speed for receiving an upstream signal from
When abnormality information is acquired by the power monitoring unit, a first timing for changing a downlink clock rate in the optical line device for transmitting a downlink signal to the optical network device to the first downlink clock rate; A bandwidth control unit that determines a second timing for changing an upstream clock rate in the optical line device for receiving an upstream signal from the optical network device to the first upstream clock rate. And light system. The bandwidth control unit changes a downlink clock speed in the optical network device for receiving the downlink signal from the optical line device based on the first timing and the second timing. And a fourth timing for changing an upstream clock speed in the optical network device for transmitting the upstream signal to the optical line device,
The optical line device sends a clock change notification including information indicating the first downlink clock rate, the first uplink clock rate, the third timing, and the fourth timing to the optical network device. Having a transmitter to transmit,
When the optical network device receives the clock change notification, at the third timing, the optical network device changes the downstream clock speed in the optical network device to the first downstream clock speed, and at the fourth timing, the The optical system according to claim 1, further comprising a second speed control unit configured to change an upstream clock speed in the optical network device to the first upstream clock speed. The optical network device holds the time when the optical line device transmits the downlink signal as the time when the optical network device receives the downlink signal,
The optical line device includes an allotted time in the optical line device assigned to receive the uplink signal, and a round-trip time for the signal to reciprocate from the optical line device to the optical network device. Have timing information,
3. The bandwidth control unit according to claim 2, wherein the bandwidth control unit determines the first timing, the second timing, the third timing, and the fourth timing based on the timing information. Light system. The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
Determining the first timing such that the downstream clock speed is changed to the first downstream clock speed by the second timing;
The optical system according to claim 3, wherein the same time as the first timing is determined as the third timing. The optical system further includes a host network that transmits the downlink signal to the optical line device, and a terminal device that transmits the uplink signal to the optical network device,
The optical line device has a first change time required for changing the downlink clock speed to the first downlink clock speed, and a first change time for changing the uplink clock speed to the first uplink clock speed. 2 change times, and
The first speed control unit is configured so that the upper network accumulates the downlink signal so that the optical line device does not receive the downlink signal during the first change time from the first timing. Instruct the upper network,
The clock change notification includes information indicating the second change time,
The second speed control unit is configured so that the terminal apparatus accumulates the uplink signal so that the optical network apparatus does not receive the uplink signal during the second change time from the fourth timing. The optical system according to claim 4, wherein an instruction is given to a terminal device. The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
4. The optical system according to claim 3, wherein the same time as the fourth timing is determined as the first timing and the third timing. The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
4. The optical system according to claim 3, wherein the same time as the second timing is determined as the first timing and the third timing. The transmission speed information includes information indicating a minimum speed of a signal transmitted and received between the optical line device and the plurality of optical network devices,
2. The speed control unit according to claim 1, wherein a clock speed capable of realizing a sum of minimum speeds of the signals is determined as the first downstream clock speed and the first upstream clock speed. Light system. An optical line device for transmitting a signal to an optical network device,
The optical line device is:
Transmission rate information indicating a minimum rate of a signal transmitted and received between the optical line device and the optical network device;
A power monitoring unit that acquires abnormality information indicating that power is not normally supplied to the optical line device or the optical network device;
When abnormality information is acquired by the power monitoring unit, based on the transmission rate information, a first downlink clock rate for the optical line device to transmit a downlink signal to the optical network device, and the optical network device A first speed controller for determining a first upstream clock speed for receiving an upstream signal from
When abnormality information is acquired by the power monitoring unit, a first timing for changing a downlink clock rate in the optical line device for transmitting a downlink signal to the optical network device to the first downlink clock rate; A bandwidth control unit for determining a second timing for changing an upstream clock rate in the optical line device for receiving an upstream signal from the optical network device to the first upstream clock rate. A characteristic optical line device. The bandwidth control unit changes a downlink clock speed in the optical network device for receiving the downlink signal from the optical line device based on the first timing and the second timing. And a fourth timing for changing an upstream clock speed in the optical network device for transmitting the upstream signal to the optical line device,
The optical line device sends a clock change notification including information indicating the first downlink clock rate, the first uplink clock rate, the third timing, and the fourth timing to the optical network device. The optical line device according to claim 9, further comprising a transmission unit for transmitting. The optical line device is:
The optical network device holds the time when the optical network device received the downlink signal as the time when the optical line device transmitted the downlink signal,
Timing information including an allocated time in the optical line device assigned to receive the uplink signal, and a round-trip time for the signal to reciprocate from the optical line device to the optical network device;
The band control unit determines the first timing, the second timing, the third timing, and the fourth timing based on the timing information. Optical line equipment. The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
Determining the first timing such that the downstream clock speed is changed to the first downstream clock speed by the second timing;
12. The optical line device according to claim 11, wherein the same time as the first timing is determined as the third timing. The optical line device is:
Connected to an upper network for transmitting the downlink signal to the optical line device;
A first change time required to change the downstream clock speed to the first downstream clock speed; a second modification time to change the upstream clock speed to the first upstream clock speed; Hold
The clock change notification includes information indicating the second change time,
The transmission unit instructs the upper network so that the upper network accumulates the downstream signal so that the optical line device does not receive the downstream signal during the first change time from the first timing. The optical line device according to claim 12, wherein: The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
12. The optical line device according to claim 11, wherein the same time as the fourth timing is determined as the first timing and the third timing. The bandwidth control unit
Determining the second timing such that the upstream clock rate is changed to the first upstream clock rate by the allocation time;
The result of subtracting the round trip time from the second timing is determined as the fourth timing,
12. The optical line device according to claim 11, wherein the same time as the second timing is determined as the first timing and the third timing. The transmission speed information includes information indicating a minimum speed of a signal transmitted and received between the optical line device and the plurality of optical network devices,
10. The optical line device according to claim 9, wherein the speed control unit determines a clock speed capable of realizing a sum of minimum speeds of the signals as the first downlink clock speed. An optical network device that receives a signal from an optical line device,
The optical network device is:
A first downlink clock rate at which the optical line device transmits a downlink signal to the optical network device; a first uplink clock rate at which the optical line device receives an uplink signal from the optical network device; A first timing for changing a downlink clock speed in the optical network apparatus for receiving the downlink signal from the line apparatus; and an uplink clock in the optical network apparatus for transmitting the uplink signal to the optical line apparatus A receiving unit that receives from the optical line device a clock change notification including information indicating second timing for changing the speed;
When the clock change notification is received, the downstream clock speed in the optical network device is changed to the first downstream clock speed at the first timing, and the upstream clock in the optical network device at the second timing. An optical network device comprising: a speed control unit that changes a speed to the first upstream clock speed. The optical network device is connected to a terminal device that transmits the uplink signal to the optical network device;
The clock change notification includes information indicating a change time for changing the upstream clock speed to the first upstream clock speed,
The speed control unit instructs the terminal device to accumulate the uplink signal so that the optical network device does not receive the uplink signal during the change time from the fourth timing. The optical network device according to claim 17.

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